Learn on PengiBig Ideas Math, Algebra 1Chapter 4: Writing Linear Functions

Lesson 3: Writing Equations of Parallel and Perpendicular Lines

Property Two lines are parallel if their slopes are exactly equal: $$m 1 = m 2$$.

Section 1

Slope Criterion for Parallel Lines and its Geometric Proof

Property

Two lines are parallel if their slopes are exactly equal:

m_1 = m_2

Geometric Proof foundation:

Alternate Interior Angles Theorem: If two lines are parallel, alternate interior angles are congruent.
SAS Congruence: If horizontal legs ( $\Delta x$ ) and vertical legs ( $\Delta y$ ) of two slope triangles are equal, and they include a 90° angle, the triangles are congruent by SAS, proving the lines share the exact same angle of elevation.

Examples

Identifying Parallel Lines: The lines $y = 3x - 2$ and $y = 3x + 5$ are parallel because both have a slope of $m = 3$ .
Checking Standard Form: To check if $2x + y = 5$ and $4x + 2y = 12$ are parallel, convert them to $y=mx+b$ . The first is $y = -2x + 5$ ( $m_1 = -2$ ). The second is $y = -2x + 6$ ( $m_2 = -2$ ). Since $m_1 = m_2$ , they are parallel.

Section 2

Perpendicular lines

Property

Two lines are perpendicular if the product of their slopes is $-1$ , that is, if

m_1 m_2 = -1

or if one of the lines is horizontal and one is vertical. The slope of one perpendicular line is the negative reciprocal of the other:

m_2 = \frac{-1}{m_1}

Examples

A line with slope $m_1 = 5$ is perpendicular to a line with slope $m_2 = -\frac{1}{5}$ because their product is $5 \times (-\frac{1}{5}) = -1$ .
The lines $y = \frac{3}{4}x + 2$ and $y = -\frac{4}{3}x - 1$ are perpendicular. Their slopes are $m_1 = \frac{3}{4}$ and $m_2 = -\frac{4}{3}$ , and their product is $(\frac{3}{4})(-\frac{4}{3}) = -1$ .
The line $y = 5$ is horizontal (slope is 0), and the line $x = 1$ is vertical (slope is undefined). These lines are perpendicular.

Explanation

Perpendicular lines intersect at a perfect right angle, like the corner of a book. Their slopes are opposites in two ways: one is positive while the other is negative, and their fractions are flipped (reciprocals).

Lesson overview

Expand to review the lesson summary and core properties.

Expand

Section 1

Slope Criterion for Parallel Lines and its Geometric Proof

Property

Two lines are parallel if their slopes are exactly equal:

m_1 = m_2

Geometric Proof foundation:

Alternate Interior Angles Theorem: If two lines are parallel, alternate interior angles are congruent.
SAS Congruence: If horizontal legs ( $\Delta x$ ) and vertical legs ( $\Delta y$ ) of two slope triangles are equal, and they include a 90° angle, the triangles are congruent by SAS, proving the lines share the exact same angle of elevation.

Examples

Identifying Parallel Lines: The lines $y = 3x - 2$ and $y = 3x + 5$ are parallel because both have a slope of $m = 3$ .
Checking Standard Form: To check if $2x + y = 5$ and $4x + 2y = 12$ are parallel, convert them to $y=mx+b$ . The first is $y = -2x + 5$ ( $m_1 = -2$ ). The second is $y = -2x + 6$ ( $m_2 = -2$ ). Since $m_1 = m_2$ , they are parallel.

Section 2

Perpendicular lines

Property

Two lines are perpendicular if the product of their slopes is $-1$ , that is, if

m_1 m_2 = -1

or if one of the lines is horizontal and one is vertical. The slope of one perpendicular line is the negative reciprocal of the other:

m_2 = \frac{-1}{m_1}

Examples

A line with slope $m_1 = 5$ is perpendicular to a line with slope $m_2 = -\frac{1}{5}$ because their product is $5 \times (-\frac{1}{5}) = -1$ .
The lines $y = \frac{3}{4}x + 2$ and $y = -\frac{4}{3}x - 1$ are perpendicular. Their slopes are $m_1 = \frac{3}{4}$ and $m_2 = -\frac{4}{3}$ , and their product is $(\frac{3}{4})(-\frac{4}{3}) = -1$ .
The line $y = 5$ is horizontal (slope is 0), and the line $x = 1$ is vertical (slope is undefined). These lines are perpendicular.

Explanation

Overview

Lesson overview

Review the lesson summary and core properties without leaving the current page.

Overview

Section 1

Slope Criterion for Parallel Lines and its Geometric Proof

Property

Two lines are parallel if their slopes are exactly equal:

m_1 = m_2

Geometric Proof foundation:

Alternate Interior Angles Theorem: If two lines are parallel, alternate interior angles are congruent.
SAS Congruence: If horizontal legs ( $\Delta x$ ) and vertical legs ( $\Delta y$ ) of two slope triangles are equal, and they include a 90° angle, the triangles are congruent by SAS, proving the lines share the exact same angle of elevation.

Examples

Identifying Parallel Lines: The lines $y = 3x - 2$ and $y = 3x + 5$ are parallel because both have a slope of $m = 3$ .
Checking Standard Form: To check if $2x + y = 5$ and $4x + 2y = 12$ are parallel, convert them to $y=mx+b$ . The first is $y = -2x + 5$ ( $m_1 = -2$ ). The second is $y = -2x + 6$ ( $m_2 = -2$ ). Since $m_1 = m_2$ , they are parallel.

Section 2

Perpendicular lines

Property

Two lines are perpendicular if the product of their slopes is $-1$ , that is, if

m_1 m_2 = -1

or if one of the lines is horizontal and one is vertical. The slope of one perpendicular line is the negative reciprocal of the other:

m_2 = \frac{-1}{m_1}

Examples

A line with slope $m_1 = 5$ is perpendicular to a line with slope $m_2 = -\frac{1}{5}$ because their product is $5 \times (-\frac{1}{5}) = -1$ .
The lines $y = \frac{3}{4}x + 2$ and $y = -\frac{4}{3}x - 1$ are perpendicular. Their slopes are $m_1 = \frac{3}{4}$ and $m_2 = -\frac{4}{3}$ , and their product is $(\frac{3}{4})(-\frac{4}{3}) = -1$ .
The line $y = 5$ is horizontal (slope is 0), and the line $x = 1$ is vertical (slope is undefined). These lines are perpendicular.